KR101669776B1 - Method and system for establishing bearer for supporting uplink semi-persistent scheduling, and user equipment - Google Patents

Abstract

The present invention provides a bearer establishment method, system and UE supporting uplink SPS scheduling, the RRC entity of the UE interpreting the RRC connection reconfiguration message sent from the eNB and receiving logical channel configuration information, an EPS bearer activation request And transmitting the logical bearer configuration information to the MAC entity of the UE and transmitting the EPS bearer activation request information and the RBID information to the NAS of the UE, Constructing LC and LCG with the RLC entity, constructing an EPS bearer with the NAS layer of the EPC according to the received EPS bearer activation request information, and associating each classifier with each logical channel , Analyzes QCI and RBID from the EPS bearer activation request information, establishes a mapping relationship between the QCI and the RBID, and transmits the mapping relationship to the MAC entity Servants is configured to include the steps: The present invention allows the UE to identify the logical channel group of uplink SPS scheduling available and effectively utilizes the scheduling resources of the uplink SPS to improve the scheduling quality of the uplink service.

Description

Technical Field [0001] The present invention relates to a bearer establishment method, system and user equipment supporting uplink semi-persistent scheduling,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mobile communication technology, and more particularly, to a bearer establishment method, a system, and a user equipment (UE) supporting uplink semi-persistent scheduling (SPS).

In a LTE system, resources are allocated by applying a dynamic scheduling scheme. However, allocation of resources by applying a dynamic scheduling scheme requires control information to be provided for each service transmission, and at the same time, As the number of users accessing the cell gradually increases, the control information required to implement the dynamic scheduling to be transmitted in the LTE system is also increased, seriously affecting the air interface communication performance of the LTE system.

In order to solve the problem that the control information continuously increases, a voice / data service, for example, a Voice over Internet Protocol (VoIP) service, in which the size of the current data packet is relatively fixed and the arrival time interval is constant, And allocates resources by applying an SPS scheduling method to the resource.

In the SPS scheduling scheme, the Evolved Node B (eNB) does not need to transmit the control information of the SPS scheduling to the UE in advance and then transmit the control information again, and the control information transmitted from the eNB by the UE and the downlink control information It is possible to transmit / receive air interface data in a fixed period according to time frequency resources in the Downlink Control Information (DCI), thereby reducing the control information overhead, and excess control information affecting the air interface communication performance of the LTE system It is possible to avoid things.

1 is a protocol stack hierarchical relationship of a control plane between a UE, an eNB, and an Evolved Packet Core (EPC) in an LTE system. As shown in FIG. 1, a UE includes a Non-Access (AS) layer includes a physical layer (PHY) entity, a medium access control (MAC) entity, a radio link control (Radio Link Control) layer, (RLC) entity, a Packet Data Convergence Protocol (PDCP) entity, and a Radio Resource Control (RRC) entity. The eNB includes a PHY entity corresponding to each entity of the AS layer of the UE, a MAC Entity, an RLC entity, a PDCP entity and an RRC entity, and the EPC includes a NAS layer corresponding to the UE's NAS layer.

2 is a diagram illustrating a logical channel (LC) and a logical channel group (LCG) between a MAC entity and a RLC entity of a UE. Between the MAC entity and the RLC entity, a total of eleven downlinks, an uplink signaling and an LC for transmitting the service are included, the eleven LCs are divided into four LCGs, and each LCG includes four LCs . The LC is identified using a Radio Bear Identity (RBID), and each LC corresponds to one RBID. The MAC entity is used to perform scheduling for services assigned by the classifier on the logical channel.

Currently, building a bearer to support uplink SPS scheduling involves building an Evolved Packet System (EPS) bearer between the NAS layer of the UE and the NAS layer of the EPC and transmitting the MAC entity of the UE and the eNB and the RLC entity Establishing a logical channel and a logical channel group supporting uplink SPS scheduling, respectively, and establishing a correspondence relationship between each classifier and a logical channel supporting each uplink SPS scheduling, thereby supporting uplink SPS scheduling And the classifier is used to assign the received uplink service to its corresponding logical channel.

According to the LTE protocol specification, the RRC entity of the UE can transmit the EPS bearer activation request information only to the NAS layer and not to the MAC entity of the AS layer. Thus, the MAC entity can not acquire a Quality of Service Identifier (QCI) included in the EPS bearer activation request information, and the QCI is used to identify the uplink service applied to the SPS scheduling scheme. Therefore, the MAC entity does not know which of the uplink services allocated on the logical channel is suitable to perform the scheduling using the SPS scheduling scheme, and the MAC entity does not know the dynamic scheduling scheme for the uplink service suitable for SPS scheduling In addition to the scheduling quality of the uplink service, the eNB and the EPC waste resources reserved for the uplink SPS scheduling.

In view of this, the embodiment of the present invention allows the MAC entity to perform the scheduling by applying the SPS scheduling method to the uplink service suitable for the SPS scheduling, thereby assuring the scheduling quality of the uplink service, and the eNB performs uplink SPS scheduling System, and UE that support uplink SPS scheduling that effectively utilizes resources reserved for the UEs.

In order to achieve the above-mentioned object, the technical solution of the embodiment according to the present invention is implemented as described above.

An embodiment according to the present invention provides a bearer establishment method supporting uplink semi persistent scheduling (SPS)

The RRC entity of the user equipment UE analyzes the RRC connection reconfiguration message transmitted from the base station eNB and generates a logical channel configuration including a radio bearer identifier (RBID) and logical grouping (LCG) information (EPS) bearer activation request information and RBID information, transmitting logical channel configuration information to a media access control (MAC) entity of the UE, and transmitting the enhanced packet system (EPS) Transmitting bearer activation request information and RBID information to a non-access layer (NAS) of the UE;

The MAC entity of the UE establishes a logical channel (LC) and a logical channel group (LCG) with a radio link control (RLC) entity according to the received logical channel configuration information and establishes a mapping relationship between the RBID and the LCG;

The NAS layer of the UE constructs an EPS bearer with the NAS layer of the EPC according to the received EPS bearer activation request information, establishes a correspondence relationship between each classifier and each of the logical channels, and generates a service quality identifier And transmitting the mapping relationship to the MAC entity by constructing a mapping relationship between the QCI and the received RBID,

A step of constructing a mapping relationship between the QCI, the RBID and the LCG according to the mapping relationship between the RBID and the LCG constructed by the MAC entity and the mapping relation between the QCI and the RBID transmitted from the NAS layer.

Preferably, after building an EPS bearer with the NAS layer of the EPC,

The NAS layer of the UE responding to the uplink direct transmission message including the EPS Bearer Activation Accept message to the eNB.

Preferably, before the RRC entity of the UE interprets the RRC connection reconfiguration message sent by the eNB,

Wherein the Evolved Packet Core Network (EPC) holds the resource according to the EPS bus establishment request information transmitted by the UE via the ENB or the UE itself and transmits the EPS bearer activation request information to the eNB;

the eNB may hold the resources according to the received EPS bearer activation request information and transmit the encapsulated RRC connection reconfiguration message to the UE in which the EPS bearer activation request information is encapsulated.

An embodiment in accordance with the present invention provides a bearer establishment system that supports uplink semi-persistent scheduling (SPS), the system comprising a Radio Resource Control (RRC) entity, a Media Access Control (MAC) entity and a non- A user equipment (UE) and a base station (eNB)

The eNB is configured to send an RRC connection reconfiguration message to the UE,

The RRC entity of the UE analyzes the RRC connection reconfiguration message transmitted from the eNB and obtains logical channel configuration information including a radio bearer identifier (RBID) and logical channel group (LCG) information, an evolved packet system (EPS) bearer activation request And to transmit logical channel configuration information to the MAC entity of the UE and to transmit the EPS bearer activation request information and the RBID information to the NAS layer of the UE,

The MAC entity of the UE establishes a logical channel (LC) and a logical channel group (LCG) with a radio link control (RLC) entity according to the received logical channel configuration information, establishes a mapping relationship between the RBID and the LCG, The mapping relationship between the RBID and the LCG, and the mapping relationship between the QCI, the RBID, and the LCG according to the mapping relationship between the QCI and the RBID transmitted from the NAS layer,

The NAS layer of the UE is configured to construct an EPS bearer with the NAS layer of the EPC according to the received EPS bearer activation request information and establish a correspondence relationship between each classifier and each logical channel, The QCI and the RBID are analyzed and a mapping relation between the QCI and the received RBID is constructed to transmit the mapping relation to the MAC entity.

Preferably, the system further comprises an evolved packet core network (EPC)

The EPC is configured to hold resources according to the Evolved Packet Core (EPS) builder request information sent by the UE via the ENB or initiated by the UE itself and to send the EPS bearer activation request information to the eNB,

Correspondingly, the eNB is also configured to withhold resources according to the received EPS bearer activation request information and encapsulate the EPS bearer activation request information in an RRC connection reconfiguration message.

An embodiment according to the present invention provides a user equipment (UE), the UE comprising a radio resource control (RRC) entity, a media access control (MAC) entity and a non-access layer (NAS)

The RRC entity interprets the RRC connection reconfiguration message transmitted from the base station eNB and obtains logical channel configuration information including a radio bearer identifier (RBID) and logical channel group (LCG) information, an evolved packet system (EPS) bearer activation Request information and RBID information, transmit logical channel configuration information to the MAC entity of the UE, and transmit the EPS bearer activation request information and RBID information to the NAS layer of the UE,

The MAC entity is configured to construct a logical channel (LC) and a logical channel group (LCG) with a radio link control (RLC) entity according to the received logical channel configuration information and establish a mapping relationship between the RBID and the LCG, The mapping relationship between the constructed RBID and the LCG and the mapping relationship between the QCI and the RBID transmitted from the NAS layer are constructed to establish the mapping relationship between the QCI, the RBID, and the LCG.

The NAS layer is configured to construct an EPS bearer with the NAS layer of the EPC according to the received EPS bearer activation request information, construct a correspondence relationship between each classifier and each logical channel, and analyze the QCI from the EPS bearer activation request information Constructs a mapping relationship between the QCI and the received RBID, and transmits the mapping relationship to the MAC entity.

Preferably, the NAS layer is also configured to respond to an uplink direct transfer message including an EPS Bearer Activation Accept message to the eNB.

As described above, the technical solution of the embodiment of the present invention is that a radio resource control (RRC) entity of a user equipment (UE) analyzes an RRC connection reconfiguration message transmitted from a base station (eNB) and stores RBID and LCG information (EPS) bearer activation request information and a radio bearer identifier (RBID) information, transmits logical channel configuration information to a media access control (MAC) entity of the UE, and transmits the EPS bearer activation request Information and RBID information to a non-access layer (NAS) of the UE; and transmitting, by the MAC entity of the UE, a logical channel (LC) with a radio link control (RLC) entity according to the received logical channel configuration information, (LCG), establishing a mapping relationship between the RBID and the LCG, and constructing an EPS bearer between the NAS layer of the UE and the NAS layer of the EPC according to the received EPS bearer activation request information, (QCI) from the EPS bearer activation request information and constructs a mapping relationship between the QCI and the received RBID, and transmits the mapping relationship to the MAC entity And a step of constructing a mapping relationship between the QCI, the RBID and the LCG according to the mapping relationship between the RBID and the LCG constructed by the MAC entity and the mapping relation between the QCI and the RBID transmitted from the NAS layer , The MAC entity can acquire the mapping relationship between QCI, RBID and LCG, and therefore can perform the scheduling by applying the SPS scheduling method to the uplink service suitable for the SPS scheduling and guarantee the scheduling quality of the uplink service, The reserved resources can be effectively utilized for uplink SPS scheduling.

1 is a protocol stack hierarchical relationship of a control plane between a UE, an eNB and an EPC in an LTE system,
2 is a diagram illustrating LC and LCG between a MAC entity and a RLC entity of a UE,
3 is a flowchart of a first embodiment of a bearer establishment method supporting uplink SPS scheduling provided in the present invention,
4 is a configuration diagram of an embodiment of a bearer establishment system supporting uplink SPS scheduling provided in the present invention,
5 is a configuration diagram of an embodiment of a UE provided in the present invention,
6 is a flowchart of a second embodiment of a bearer establishment method supporting uplink SPS scheduling provided by the present invention.

A first embodiment of a bearer construction method supporting the uplink SPS scheduling provided in the present invention is as shown in FIG. 3, and the method includes the following steps.

Step 301: The RRC entity of the UE analyzes the RRC connection reconfiguration message transmitted from the eNB and obtains the logical channel configuration information including the RBID and the LCG information, the EPS bearer activation request information and the RBID information, And transmits the EPS bearer activation request information and the RBID information to the NAS layer of the UE.

Step 302: The MAC entity of the UE establishes a logical channel (LC) and a logical channel group (LCG) with a radio link control (RLC) entity according to the received logical channel configuration information and establishes a mapping relationship between the RBID and the LCG.

Step 303: The NAS layer of the UE constructs an EPS bearer with the NAS layer of the EPC according to the received EPS bearer activation request information, establishes a correspondence relationship between each classifier and each logical channel, (QCI), constructs a mapping relationship between the analyzed QCI and the received RBID, and transmits the mapping relation to the MAC entity.

Step 304: The mapping entity between the QCI, the RBID and the LCG is constructed according to the mapping relationship between the RBID and the LCG constructed by the MAC entity and the mapping relation between the QCI and the RBID transmitted from the NAS layer.

Preferably, after constructing the EPS bearer with the NAS layer of the EPC in step 303,

The NAS layer of the UE responding to the uplink direct transmission message including the EPS Bearer Activation Accept message to the eNB.

Preferably, before the RRC entity of the UE in step 301 analyzes the RRC connection reconfiguration message transmitted from the eNB,

The EPC holds the resources according to the EPS bus establishing request information transmitted by the UE via the ENB or the UE itself and transmits the EPS bearer activation request information to the eNB;

the eNB may hold the resources according to the received EPS bearer activation request information and transmit the encapsulated RRC connection reconfiguration message to the UE in which the EPS bearer activation request information is encapsulated.

4, the system includes an eNB 401, an RRC entity 4021, a MAC entity 4022, and a NAS 404. The bearer establishment system supports uplink SPS scheduling according to an embodiment of the present invention. A layer 4023, and a UE 402 including a layer 4023,

The eNB 401 is configured to send an RRC connection reconfiguration message to the UE 402,

The RRC entity 4021 of the UE 402 analyzes the RRC connection reconfiguration message transmitted from the eNB 401 and obtains the logical channel configuration information including the RBID and LCG information, the EPS bearer activation request information, and the RBID information , To transmit logical channel configuration information to the MAC entity 4022 of the UE 402 and to transmit the EPS bearer activation request information and RBID information to the NAS layer 4023 of the UE 402,

The MAC entity 4022 of the UE 402 constructs an LC and an LCG with the RLC entity according to the received logical channel configuration information, establishes a mapping relationship between the RBID and the LCG, The mapping relationship between the QCI, the RBID, and the LCG is constructed according to the mapping relation between the QCI and the RBID transmitted from the layer 4023,

The NAS layer 4023 of the UE 402 is configured to construct an EPS bearer with the NAS layer of the EPC according to the received EPS bearer activation request information and construct a correspondence relationship between each classifier and each logical channel, The QCI is interpreted from the activation request information, and a mapping relation between the QCI and the received RBID is constructed to transmit the mapping relation to the MAC entity 4022.

Preferably, the system further comprises an EPC 403, the EPC 403 being operable to transmit the EPS scaler establishment request information transmitted by the UE 402 via the eNB 401 or by the UE 402 itself And to send the EPS bearer activation request information to the eNB 401,

Correspondingly, the eNB 401 is also configured to hold resources according to the received EPS bearer activation request information and to encapsulate the EPS bearer activation request information in an RRC connection reconfiguration message.

5, the UE 402 includes an RRC entity 4021, a MAC entity 4022, and a NAS layer 4023,

The RRC entity 4021 analyzes the RRC connection reconfiguration message transmitted from the eNB and obtains logical channel configuration information including RBID and LCG information, EPS bearer activation request information and RBID information, and outputs logical channel configuration information to the UE 402 to the MAC entity 4022 and to transmit the EPS bearer activation request information and RBID information to the NAS layer 4023 of the UE 402,

The MAC entity 4022 is configured to construct LC and LCG with the RLC entity according to the received logical channel configuration information and establish a mapping relationship between the RBID and the LCG, The mapping relationship between QCI, RBID and LCG is constructed according to the mapping relation between QCI and RBID transmitted from the QCB 4023,

The NAS layer 4023 is configured to construct an EPS bearer with the NAS layer of the EPC according to the received EPS bearer activation request information and establish a correspondence relationship between each classifier and each logical channel, And transmits the mapping relation to the MAC entity 4022 by constructing a mapping relationship between the QCI and the received RBID.

Preferably, the NAS layer 4023 is also configured to respond to an uplink direct transfer message including an EPS Bearer Activation Accept message to the eNB.

Hereinafter, a second embodiment of a bearer establishment method supporting uplink SPS scheduling provided by the present invention will be described. As shown in FIG. 6, the method includes the following steps.

Step 601: The EPC suspends the resource according to the EPS bus establishment request information transmitted by the UE via the ENB or by the UE itself and transmits the EPS bearer activation request information to the eNB.

Step 602: The eNB suspends the resource according to the received EPS bearer activation request information and transmits the encapsulated RRC connection reconfiguration message to the UE.

Step 603: The RRC entity of the UE analyzes the RRC connection reconfiguration message transmitted from the eNB and obtains the logical channel configuration information including the RBID and the LCG information, the EPS bearer activation request information and the RBID information, And transmits the EPS bearer activation request information and the RBID information to the NAS layer of the UE.

Step 604A: The MAC entity of the UE constructs the LC and LCG with the RLC entity according to the received logical channel configuration information, and establishes a mapping relationship between the RBID and the LCG.

Step 604B: The NAS layer of the UE establishes an EPS bearer with the NAS layer of the EPC according to the received EPS bearer activation request information, establishes a correspondence relationship between each classifier and each logical channel, and includes an EPS bearer activation accept message in the eNB And transmits the uplink direct transmission message.

Step 604C: The NAS layer analyzes the QCI in the EPS bearer activation request information and constructs a mapping relationship between the QCI and the received RBID, and transmits the mapping relationship to the MAC entity.

Step 605A: The MAC entity establishes a mapping relationship between the QCI, the RBID, and the LCG according to the mapping relationship between the constructed RBID and the LCG and the mapping relationship between the QCI and the RBID transmitted from the NAS layer.

Step 605B: The eNB sends the received uplink direct transmission message to the EPC.

When the bearer construction method supporting the uplink SPS scheduling is applied, the MAC entity can establish a mapping relationship between QCI, RBID, and LCG, so that the MAC entity can establish a mapping relationship between QCI, RBID, and LCG The SPS scheduling scheme is applied to the uplink service suitable for the SPS scheduling according to the mapping relationship between the uplink service and the uplink SPS scheduling, thereby ensuring the scheduling quality of the uplink service and effectively utilizing the reserved resources for the uplink SPS scheduling.

The foregoing is merely a preferred embodiment of the present invention and is not intended to limit the scope of protection of the present invention.

Claims (7)

A bearer establishment method supporting uplink semi-persistent scheduling (SPS), comprising:
(RRC) entity of the user equipment (UE) analyzes the RRC connection reconfiguration message transmitted from the base station (eNB) and generates a logical channel configuration including a radio bearer identifier (RBID) and logical channel group (LCG) (EPS) bearer activation request information and RBID information, transmits logical channel configuration information to the MAC entity of the UE, and transmits the EPS bearer activation request information and the RBID information to the UE To an access layer (NAS)
The MAC entity of the UE establishes a logical channel (LC) and a logical channel group (LCG) with a radio link control (RLC) entity according to the received logical channel configuration information and establishes a mapping relationship between the RBID and the LCG;
The NAS of the UE constructs an EPS bearer with the NAS of the evolved packet core (EPC) according to the received EPS bearer activation request information, establishes a correspondence relation between each classifier and each logical channel, Analyzing a quality of service identifier (QCI), establishing a mapping relationship between the analyzed QCI and a received RBID, and transmitting the mapping relationship to a MAC entity;
Constructing a mapping relationship between the QCI, the RBID, and the LCG according to the mapping relationship between the RBID and the LCG constructed by the MAC entity and the mapping relation between the QCI and the RBID transmitted from the NAS; How to build a bearer that supports SPS. The method according to claim 1,
After constructing an EPS bearer with the NAS of the EPC,
Further comprising the step of the NAS of the UE responding with an uplink direct transfer message including an EPS Bearer Activation Accept message to the eNB. The method according to claim 1,
Before the RRC entity of the UE interprets the RRC connection reconfiguration message sent by the eNB,
Wherein the Evolved Packet Core (EPC) retires resources according to EPS bus setup information transmitted by the UE via the eNB or initiated by the UE itself, and transmits the EPS bearer activation request information to the eNB;
wherein the eNB holds the resources according to the received EPS bearer activation request information and transmits the encapsulated RRC connection reconfiguration message to the UE in which the EPS bearer activation request information is encapsulated. Way. A bearer establishment system supporting uplink semi persistent scheduling (SPS), comprising:
The system includes a user equipment (UE) and a base station (eNB) including a radio resource control (RRC) entity, a media access control (MAC) entity and a non-access layer (NAS)
The eNB is configured to send an RRC connection reconfiguration message to the UE,
The RRC entity of the UE analyzes the RRC connection reconfiguration message transmitted from the eNB and obtains logical channel configuration information including a radio bearer identifier (RBID) and logical channel group (LCG) information, an evolved packet system (EPS) bearer activation request And to transmit logical channel configuration information to the MAC entity of the UE and to transmit the EPS bearer activation request information and the RBID information to the NAS of the UE,
The MAC entity of the UE establishes a logical channel (LC) and a logical channel group (LCG) with a radio link control (RLC) entity according to the received logical channel configuration information, establishes a mapping relationship between the RBID and the LCG, The mapping relationship between the RBID and the LCG, and the mapping relationship between the QCI, the RBID, and the LCG according to the mapping relationship between the QCI and the RBID transmitted from the NAS,
The NAS of the UE is configured to construct an EPS bearer with the NAS of the evolved packet core (EPC) according to the received EPS bearer activation request information, and to establish correspondence between each classifier and each logical channel, (QCI) and RBID from the information, construct a mapping relationship between the analyzed QCI and the received RBID, and transmit the mapping relationship to the MAC entity. Bearer building system. The method of claim 4,
The system further comprises the EPC,
Wherein the EPC is configured to hold resources according to Evolved Packet System (EPS) builder request information sent by the UE or initiated by the UE itself via the eNB and to send EPS Bearer Activation Request information to the eNB,
Correspondingly, the eNB is further configured to withhold resources according to the received EPS bearer activation request information and encapsulate the EPS bearer activation request information in an RRC connection reconfiguration message. In a user equipment (UE)
The UE includes a radio resource control (RRC) entity, a media access control (MAC) entity, and a non-access layer (NAS)
The RRC entity interprets the RRC connection reconfiguration message transmitted from the base station eNB and obtains logical channel configuration information including a radio bearer identifier (RBID) and logical channel group (LCG) information, an evolved packet system (EPS) bearer activation Request information and RBID information, transmit logical channel configuration information to the MAC entity of the UE, and transmit the EPS bearer activation request information and the RBID information to the NAS of the UE,
The MAC entity is configured to construct a logical channel (LC) and a logical channel group (LCG) with a radio link control (RLC) entity according to the received logical channel configuration information and establish a mapping relationship between the RBID and the LCG, The mapping relationship between the constructed RBID and the LCG and the mapping relationship between the QCI and the RBID transmitted from the NAS constitute a mapping relationship between the QCI, the RBID and the LCG.
The NAS is constructed to construct an EPS bearer with the NAS of the EPC according to the received EPS bearer activation request information, to construct a correspondence relationship between each classifier and each logical channel, and to interpret the QCI from the EPS bearer activation request information, And construct a mapping relationship between the analyzed QCI and the received RBID to transmit the mapping relationship to the MAC entity. The method of claim 6,
Wherein the NAS is further configured to respond to an uplink direct transfer message including an EPS Bearer Activation Accept message to the eNB.

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